The invention provides a method for selecting a color for a chemistry or instrument based upon a parameter of a test, the method including: identifying a color corresponding to a parameter of a test for the parameter; selecting, if the color corresponding to the parameter has not previously been used for another parameter, the color for designating a chemistry or an instrument as corresponding to the parameter; selecting, if the color corresponding to the parameter has previously been used for another parameter, a different color other than the color for designating a chemistry or an instrument as corresponding to the parameter, wherein the selecting a color other than the color comprises identifying a color having a measure of change in visual perception of the different color against other previously selected colors a predetermined value from the other previously selected colors; and utilizing the selected colors for parameters across both chemistries (102, 104, 105) and instruments (101, 103) that are utilized in tests for the parameters.

The disclosure relates to multi-well plates having fluidic connections between neighboring wells that are useful to produce a cell culture substrate and compliant with American National Standards Institute of the Society for Laboratory Automation and Screening (ANSI/SLAS) microplate standards

The invention relates to a system and method for traceability of transport of containers of biological samples, arranged in a containment rack, from a drawing point to an analysis point, in which a preparation apparatus is able, for each containment rack going out from the drawing point, to identify the containment rack, to detect the measurement of the outgoing mass of the containment rack and to store the measurement of the outgoing mass in a centralized database, and in which a check-in apparatus is able, for each containment rack coming to the analysis point, to identify the containment rack, to detect the measurement of the incoming mass of the containment rack and to compare the measurement of the outgoing mass with the detected measurement of the incoming mass, generating an alert if the measurement of the outgoing mass is different from the measurement of the incoming mass.

A flow cell applicator system can include a flow cell applicator including multiple flow cells to deposit multiple substance spots on a deposition surface, and a positioning assembly to position, to dock, and to unlock the multiple flow cells relative to the deposition surface. The substance spots can be depositable when the multiple flow cells are docked on the deposition surface. The flow cell applicator system can also include a spot deposition identifier operably associated with a processor to: record data related to substance spots as applied on the deposition surface, identify data related to substance spots previously deposited on the deposition surface, or both.

A simple configuration is used to make a determination of suitability of a cartridge including a case where the cartridge is unused. An examination system (1) includes a cartridge (2) to which identification information is assigned and an examination device (3) that acquires the identification information and performs an examination. The examination system (1) makes a determination of suitability of the cartridge based on the identification information and controls an operation of the examination device in accordance with a result of the determination.

A laboratory instrument for processing at least one sample is disclosed. The laboratory instrument includes at least one housing having at least one sample processing device disposed therein, at least one reagent storage compartment reversibly removable from the housing, and at least one safety indicator. The safety indicator is configured for indicating if the reagent storage compartment has been removed from the housing and reinserted into the housing. The laboratory instrument is configured for automatically altering a detectable state of the safety indicator during the process of removing and reinserting the reagent storage compartment.

A stack of histology cassettes configured to be inserted into a hopper of a printer, wherein each histology cassette in the stack includes a bottom face, a top face opposite the bottom face, a front face, a rear face opposite the front face, a first lateral face and a second lateral face opposite the first lateral face. The top face of the histology cassette is open to allow a sample to be received within the histology cassette. The histology cassettes have substantially the same orientation within the stack. The histology cassettes in the stack are arranged with a first histology cassette at the bottom of a stack, and each subsequent histology cassette in the stack up to a last histology cassette in the stack is arranged with its bottom face positioned on the top face of a preceding histology cassette in the stack.

The equipment item for automatically managing a plurality of biological samples placed in a respective sample jar includes a storage container for sample jars having a plurality of housings, an apparatus with a reader of encoded identification data affixed on the sample jars placed in the container, a device for determining data representative of the position of each sample jar within the container, and a device for rotating the container, and a computer processor connected to the apparatus. The container includes, in the immediate vicinity of each housing, a shape appearing recessed or raised, while the device for determining data representative of the position of each sample jar is defined by a detector for the shape.

Method, apparatus, and computer program product are provided for anonymized diagnosis using lateral flow assays. In some embodiments, a test card includes one or more lateral flow assay (LFA) with one or more test patterns (e.g., full line, partial line, dot), one or more dummy patterns, and one or more control patterns. To visually encode LFA results, at manufacture, one or more lines/dots containing true results of the LFA(s) each has a position mixed with other “dummy” lines/dots, in randomized position patterns selected from among a plurality of possible position patterns. An optical machine-readable representation of data (e.g., QR code) is attached to the test card and encodes test card identification information (e.g., lot number, serial number, test type) associated with the test card. In some embodiments, a passcode card having a scrapeable coating that conceals a passcode associated with the test card is removably attached to the test card.

A method and a system for controlled usage of a laboratory glassware 123 comprises defining the usage control of the laboratory glassware 123, at a remote server 130, by receiving a first information from a computing device 120, and thereby generating a virtual stamp associated with the laboratory glassware 123. The first information is received over a communication link 160 from the computing device 120 by scanning a QR code associated with the glassware 123 using a scanning module 210 of the computing device 120. The remote server 130 allows an authorized user to define the usage control information in the virtual stamp for the controlled usage of the glassware 123.